Computed tomography scan imaging of natural open fractures in a porous rock; geometry and fluid flow

Wennberg, Ole Petter; Rennan, Lars; Basquet, Remy

doi:10.1111/j.1365-2478.2009.00784.x

Cited by 28 publications

(11 citation statements)

References 14 publications

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“…(e.g. Wennberg et al, 2009) or when evaluating the effects of specific reactions that Table 4 Accuracy of segmentation on µCT image by means of dual-thresholding method.…”

Section: Discussionmentioning

confidence: 99%

3D quantification of mineral components and porosity distribution in Westphalian C sandstone by microfocus X-ray computed tomography

Long

Swennen

Foubert

et al. 2009

Sedimentary Geology

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“…(e.g. Wennberg et al, 2009) or when evaluating the effects of specific reactions that Table 4 Accuracy of segmentation on µCT image by means of dual-thresholding method.…”

Section: Discussionmentioning

confidence: 99%

3D quantification of mineral components and porosity distribution in Westphalian C sandstone by microfocus X-ray computed tomography

Long

Swennen

Foubert

et al. 2009

Sedimentary Geology

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“…They may also allow assessment of bulk material properties, such as porosity and permeability (e.g. Grader et al, 2000;Wennberg et al, 2009;Voorn et al, 2015), and act as a historical record of the core once it has been subsampled. For these reasons and others, it is now common to obtain X-ray computed tomographic (CT) scans of core upon its recovery during drilling projects (Rothwell and Rack, 2006;Withjack et al, 2003).…”

Section: Introductionmentioning

confidence: 99%

A comparison of the use of X-ray and neutron tomographic core scanning techniques for drilling projects: insights from scanning core recovered during the Alpine Fault Deep Fault Drilling Project

2017

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Abstract. It is now commonplace for non-destructive X-ray computed tomography (CT) scans to be taken of core recovered during a drilling project. However, other forms of tomographic scanning are available, and these may be particularly useful for core that does not possess significant contrasts in density and/or atomic number to which X-rays are sensitive. Here, we compare CT and neutron tomography (NT) scans of 85 mm diameter core recovered during the first phase of the Deep Fault Drilling Project (DFDP-1) through New Zealand's Alpine Fault. For the instruments used in this study, the highest resolution images were collected in the NT scans. This allows clearer imaging of some rock features than in the CT scans. However, we observe that the highly neutron beam attenuating properties of DFDP-1 core diminish the quality of images towards the interior of the core. A comparison is also made of the suitability of these two scanning techniques for a drilling project. We conclude that CT scanning is far more favourable in most circumstances. Nevertheless, it could still be beneficial to take NT scans over limited intervals of suitable core, where varying contrast is desired.

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“…Iodine, with its large atomic number (Z), is one of the most commonly used contrast agents in nonmedical science and engineering. For example, it is used in laboratory experiments by means of medical and microfocus X-ray computed tomography (CT) systems to help visualize the flow or diffusion of fluids in complex, porous geological media [2][3][4][5]. Humans and animals have a low density (≈1-2 g/cm 3 ); however, porous geological media generally have a much higher density (≈2-4 g/cm 3 ), which means that a pore fluid with an iodine concentration much larger than that needed for the CT measurements of humans and animals must be used (e.g., a KI solution of 0.6 mol/L [2]).…”

Section: Introductionmentioning

confidence: 99%

Optimizing contrast agents with respect to reducing beam hardening in nonmedical X-ray computed tomography experiments

Nakashima

Nakano

2014

Journal of X-Ray Science and Technology

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Iodine is commonly used as a contrast agent in nonmedical science and engineering, for example, to visualize Darcy flow in porous geological media using X-ray computed tomography (CT). Undesirable beam hardening artifacts occur when a polychromatic X-ray source is used, which makes the quantitative analysis of CT images difficult. To optimize the chemistry of a contrast agent in terms of the beam hardening reduction, we performed computer simulations and generated synthetic CT images of a homogeneous cylindrical sand-pack (diameter, 28 or 56 mm; porosity, 39 vol.%) saturated with aqueous suspensions of heavy elements assuming the use of a polychromatic medical CT scanner. The degree of cupping derived from the beam hardening was assessed using the reconstructed CT images to find the chemistry of the suspension that induced the least cupping. The results showed that (i) the degree of cupping depended on the position of the K absorption edge of the heavy element relative to peak of the polychromatic incident X-ray spectrum, (ii) 53 I was not an ideal contrast agent because it causes marked cupping, and (iii) a single element much heavier than 53I (64Gd to 79Au) reduced the cupping artifact significantly, and a four-heavy-element mixture of elements from 64Gd to 79Au reduced the artifact most significantly.

show abstract

Computed tomography scan imaging of natural open fractures in a porous rock; geometry and fluid flow

Cited by 28 publications

References 14 publications

3D quantification of mineral components and porosity distribution in Westphalian C sandstone by microfocus X-ray computed tomography

3D quantification of mineral components and porosity distribution in Westphalian C sandstone by microfocus X-ray computed tomography

A comparison of the use of X-ray and neutron tomographic core scanning techniques for drilling projects: insights from scanning core recovered during the Alpine Fault Deep Fault Drilling Project

Optimizing contrast agents with respect to reducing beam hardening in nonmedical X-ray computed tomography experiments

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